Bit 2 (MSB) of the 3-bit data bus transferring data from the MAC to the LAN Interface compliant PLC. For detailed information on this signal, refer to the current version of the Core Logic Design Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

B7

GND

Power supply and signal ground return path.

A8

LAN_TXD0

Bit 0 (LSB) of the 3-bit data bus transferring data from the MAC to the LAN Interface compliant PLC. For detailed information on this signal, refer to the current version of the Core Logic Design Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

B8

LAN_TXD1

Bit 1 of the 3-bit data bus transferring data from the MAC to the LAN Interface compliant PLC. For detailed information on this signal, refer to the current version of the Core Logic Design Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

A9

GND

Power supply and signal ground return path.

B9

LAN_RSTSYNC

This is a dual function pin that provides either a reset pulse or a synchronization pulse from the MAC to the LAN Interface compliant PLC. For detailed information on this signal, refer to the current version of the Core Logic Design Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

A10

LAN_CLK

Data clock from a LAN Interface compliant PLC to the Media Access Controller (MAC). The nominal frequency of this signal determines the data transfer rate between the PLC and the MAC. For detailed information, refer to the current version Core Logic Design Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

B10

GND

Power supply and signal ground return path.

A11

LAN_RXD1

Bit 1 of the 3-bit data bus transferring data from the LAN Interface compliant PLC device to the MAC. For detailed information on this signal, refer to the current version of the Core Logic Design Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

B11

LAN_RXD2

Bit 2 (MSB) of the 3-bit data bus transferring data from the LAN Interface compliant PLC to the MAC. For detailed information on this signal, refer to the current version of the Core Logic Design Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

A12

RESERVED

-

RESERVED

B12

LAN_RXD0

Bit 0 (LSB) of the 3-bit data bus transferring data from the LAN Interface compliant PLC device to the MAC. For detailed information on this signal, refer to the current version of the Core Logic Design Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

A13

USB+

Positive side of the differential USB 1.x or 2.0 data signal. For more information, refer to the Universal Serial Bus Specification. The state of this signal during reset must meet the Universal Serial Bus Specification.

B13

GND

Power supply and signal ground return path.

A14

GND

Power supply and signal ground return path.

B14

RESERVED

-

RESERVED

A15

USB-

Negative side of the differential USB 1.x or 2.0 data signal. For more information, refer to the Universal Serial Bus Specification. The state of this signal during reset must meet the Universal Serial Bus Specification.

B15

+5Vdual

Positive 5-volt main/standby power supply (can be used for USB power). +5Vdual supply provides full-rated power capacity during working or full-on state, and a limited power capacity during sleep or suspended states. When a +5Vdual supply is not available, this pin must be connected to a +5 volt standby power source. This signal must not be connected to a +5VD, as doing so eliminates the possibility of deep-sleep wake capabilities.

A16

+12V

Positive 12-volt main power supply

B16

USB_OC#

USB bus over-current signal. For more information, refer to the Universal Serial Bus Specification. The state of this signal during reset must meet the Universal Serial Bus Specification.

A17

GND

Power supply and signal ground return path.

B17

GND

Power supply and signal ground return path.

A18

+3.3Vdual

Positive 3.3-volt main/standby power supply. +3.3Vdual supply provides full-rated power capacity during working or full-on state, and a limited power capacity during sleep or suspended states. When +3.3Vdual is not available, this pin must be connected to a +3.3-volt standby power source. This signal must not be connected to a +3.3VD, as doing so eliminates the possibility of deep-sleep wake capabilities.

B18

-12V

Negative 12-volt main power supply

A19

+5VD

Positive 5-volt main digital power supply

B19

+3.3VD

Positive 3.3-volt main digital power supply

A20

GND

Power supply and signal ground return path.

B20

GND

Power supply and signal ground return path.

A21

EE_DIN

This signal carries serial data from the core logic MAC Microwire* interface to the Microwire EEPROM (which stores MAC/PLC/PHY specific information) on the CNR board. The EE_DIN signal on the CNR connector must be connected to the DIN pin on the Microwire EEPROM.

B21

EE_DOUT

This signal carries serial data from the Microwire EEPROM (which stores MAC/PLC/PHY specific information) on the CNR board to the core logic MAC Microwire* interface. The EE_DOUT signal on the CNR connector must be connected to the DOUT pin on the Microwire EEPROM.

A22

EE_CS

The CNR board uses this signal to enable the serial EEPROM devices on the CNR board. When EE_CS is high (one) the Microwire EEPROM (for the LAN Interface) becomes active. When EE_CS is low (zero) the EEPROM is inactive. The resting state of this signal is low (zero). The state of this signal during reset must be low (zero).

B22

EE_SHCLK

This signal is the serial clock signal from the core logic MAC Microwire* interface to the Microwire EEPROM (which stores MAC/PLC/PHY specific information) on the CNR board.

A23

SMB_A1

This signal is bit 1 of the 3-bit address of the SMBus EEPROM on the CNR board. Refer to Section 6.1.1.2 for detailed information on the connectivity of this signal. The state of this signal during reset must be the SMBus address for the CNR board.

B23

GND

Power supply and signal ground return path.

A24

SMB_A2

This signal is bit 2 (MSB) of the 3-bit address of the SMBus EEPROM on the CNR board. Refer to Section 6.1.1.2 for detailed information on the connectivity of this signal. The state of this signal during reset must be the SMBus address for the CNR board.

B24

SMB_A0

This signal is bit 0 (LSB) of the 3-bit address of the SMBus EEPROM on the CNR board. Refer to Section 6.1.1.2 for detailed information on the connectivity of this signal. The state of this signal during reset must be the SMBus address of the CNR board.

A25

SMB_SDA

Bi-directional serial data line between the SMBus master to SMBus slave device(s) on the CNR board. For detailed information on this signal, refer to the current version of the System Management Bus Specification. The reset state of this signal must meet the current version of the System Management Bus Specification.

B25

SMB_SCL

Serial clock line from the SMBus master to SMBus slave device(s) on the CNR board. For detailed information on this signal, refer to the current version of the System Management Bus Specification. The reset state of this signal must meet the current version of the System Management Bus Specification.

A26

AC97_RESET#

Active low AC97 link reset signal. For detailed information, refer to the current version of the AC97 Component Specification. The reset state of this signal must meet the requirements of the current version of the AC97 Component Specification.

B26

CDC_DN_ENAB#

CDC_DN_ENAB# indicates whether the motherboard or the CNR is in control, or mastering, the AC97 interface attached to the CNR Connector. When at a logic low level, the CDC_DN_ENAB# signal indicates that the primary codec on the motherboard is active and controlling the AC97 Interface. In addition, the CNR will, when CDC_DN_ENAB# is low, demote its codecs to the next available address and to the next available SDATA_IN signal. See Section 3.3.1 for more details on the implementation of the CDC_DN_ENAB# signal. When at a logic high level, the CDC_DN_ENAB# signal indicates that a primary codec on the CNR is taking control of the AC97 Interface. In addition, the motherboard will, when CDC_DN_ENAB# is high, disable all of its codecs. See Section 3.3.1 for more details of how to implement the CDC_DN_ENAB# signal.

A27

RESERVED

-

RESERVED

B27

GND

Power supply and signal ground return path.

A28

AC97_SDATA_IN1

AC97 serial data from an AC97-compliant codec (primary or secondary) to an AC97-compliant Controller. For detailed information, refer to the current version of the AC97 Component Specification. The reset state of this signal must meet the requirements of the current version of the AC97 Component Specification.

B28

AC97_SYNC

Synchronization pulse from an AC97-compliant controller to all of the AC97- compliant codecs on the AC link. This signal is nominally a 1.3 µS wide pulse, which is used to synchronize the AC link. For detailed information, refer to the current version of the AC97 Component Specification. The reset state of this signal must meet the requirements of the current version of the AC97 Component Specification.

A29

AC97_SDATA_IN0

AC97 serial data from a primary AC97-compliant codec to an AC97-compliant Controller. For detailed information, refer to the current version of the AC97 Component Specification. The reset state of this signal must meet the requirements of the current version of the AC97 Component Specification.

B29

AC97_SDATA_OUT

AC97 serial data from an AC97-compliant controller to all of the AC97- compliant codecs on the link. For detailed information, refer to the current version of the AC97 Component Specification. The reset state of this signal must meet the requirements of the current version of the AC97 Component Specification.

A30

GND

Power supply and signal ground return path.

B30

AC97_BITCLK

Serial data clock from primary codec to AC97 Controller and any non-primary codecs. The nominal frequency of this signal is 12.288 MHz. For detailed information, refer to the current version of the AC97 Component Specification. AC97_BITCLK is an output from a primary codec and an input to non-primary codecs. The reset state of this signal must meet the requirements of the current version of the AC97 Component Specification.

Note: Direction is motherboard relative card.

Type B CNR connector

Pin

Signal

Type

Description

A1

MII_MDC

Management data clock signal from Management Data Controller to the MII compliant PHY. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

B1

MII_MDIO

Management data input/output signal between the Management Data Controller and the MII compliant PHY. This signal is used to carry bi-directional data for control and status registers. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

A2

MII_CRS

Carrier sense signal from the MII compliant PHY to the MAC. This signal indicates that there is traffic on the LAN wire. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

B2

MII_COL

Collision detect signal from the MII compliant PHY to the MAC. This signal indicates that a collision has occurred on the LAN wire. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

A3

GND

Power supply and signal ground return path.

B3

MII_TXC

Data clock from the MAC to the MII compliant PHY. For detailed information, refer to the current version Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

A4

MII_RXDV

Receive data valid signal from the MII compliant PHY to the MAC. This signal indicates that valid data is available on the MII_RXD[3:0] signals. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

B4

GND

Power supply and signal ground return path.

A5

MII_RXC

Data clock from a MII Interface compliant PHY to the MAC. For detailed information, refer to the current version Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

B5

MII_RXERR

Receive error signal from the MII compliant PHY to the MAC. This signal indicates that an error has occurred during frame reception. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

A6

GND

Power supply and signal ground return path.

B6

MII_TXD3

Bit 3 (MSB) of the 4-bit data bus transferring data from the MAC to the MII compliant PHY. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

A7

MII_TXD2

Bit 2 of the 4-bit data bus transferring data from the MAC to the MII compliant PHY. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

B7

GND

Power supply and signal ground return path.

A8

MII_TXD0

Bit 0 (LSB) of the 4-bit data bus transferring data from the MAC to the MII compliant PHY. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

B8

MII_TXD1

Bit 1 of the 4-bit data bus transferring data from the MAC to the MII compliant PHY. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

A9

GND

Power supply and signal ground return path.

B9

MII_TXEN

Transmit enable signal from the MAC to the MII compliant PHY. This signal indicates that the available on the MII_TXD[3:0] signals can be placed on the LAN wire. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

A10

RESERVED

RESERVED

B10

GND

Power supply and signal ground return path.

A11

MII_RXD1

Bit 1 of the 4-bit data bus transferring data from the MII compliant PHY to the MAC. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

B11

MII_RXD2

Bit 2 of the 4-bit data bus transferring data from the MII compliant PHY to the MAC. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

A12

MII_RXD3

Bit 3 (MSB) of the 4-bit data bus transferring data from the MII compliant PHY to the MAC. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

B12

MII_RXD0

Bit 0 (LSB) of the 4-bit data bus transferring data from the MII compliant PHY to the MAC. For detailed information on this signal, refer to the current version of the Core Logic Design Specification and the IEEE 802.3u Specification. The reset state of this signal must meet the requirements set forth in the current version of the Core Logic Design Specification.

A13

USB+

Positive side of the differential USB 1.x or 2.0 data signal. For more information, refer to the Universal Serial Bus Specification. The state of this signal during reset must meet the Universal Serial Bus Specification.

B13

GND

Power supply and signal ground return path.

A14

GND

Power supply and signal ground return path.

B14

RESERVED

-

RESERVED

A15

USB-

Negative side of the differential USB 1.x or 2.0 data signal. For more information, refer to the Universal Serial Bus Specification. The state of this signal during reset must meet the Universal Serial Bus Specification.

B15

+5Vdual

Positive 5-volt main/standby power supply (can be used for USB power). +5Vdual supply provides full-rated power capacity during working or full-on state, and a limited power capacity during sleep or suspended states. When a +5Vdual supply is not available, this pin must be connected to a +5 volt standby power source. This signal must not be connected to a +5VD, as doing so eliminates the possibility of deep-sleep wake capabilities.

A16

+12V

Positive 12-volt main power supply

B16

USB_OC#

USB bus over-current signal. For more information, refer to the Universal Serial Bus Specification. The state of this signal during reset must meet the Universal Serial Bus Specification.

A17

GND

Power supply and signal ground return path.

B17

GND

Power supply and signal ground return path.

A18

+3.3Vdual

Positive 3.3-volt main/standby power supply. +3.3Vdual supply provides full-rated power capacity during working or full-on state, and a limited power capacity during sleep or suspended states. When +3.3Vdual is not available, this pin must be connected to a +3.3-volt standby power source. This signal must not be connected to a +3.3VD, as doing so eliminates the possibility of deep-sleep wake capabilities.

B18

-12V

Negative 12-volt main power supply

A19

+5VD

Positive 5-volt main digital power supply

B19

+3.3VD

Positive 3.3-volt main digital power supply

A20

GND

Power supply and signal ground return path.

B20

GND

Power supply and signal ground return path.

A21

EE_DIN

This signal carries serial data from the core logic MAC Microwire* interface to the Microwire EEPROM (which stores MAC/PLC/PHY specific information) on the CNR board. The EE_DIN signal on the CNR connector must be connected to the DIN pin on the Microwire EEPROM.

B21

EE_DOUT

This signal carries serial data from the Microwire EEPROM (which stores MAC/PLC/PHY specific information) on the CNR board to the core logic MAC Microwire* interface. The EE_DOUT signal on the CNR connector must be connected to the DOUT pin on the Microwire EEPROM.

A22

EE_CS

The CNR board uses this signal to enable the serial EEPROM devices on the CNR board. When EE_CS is high (one) the Microwire EEPROM (for the LAN Interface) becomes active. When EE_CS is low (zero) the EEPROM is inactive. The resting state of this signal is low (zero). The state of this signal during reset must be low (zero).

B22

EE_SHCLK

This signal is the serial clock signal from the core logic MAC Microwire* interface to the Microwire EEPROM (which stores MAC/PLC/PHY specific information) on the CNR board.

A23

SMB_A1

This signal is bit 1 of the 3-bit address of the SMBus EEPROM on the CNR board. Refer to Section 6.1.1.2 for detailed information on the connectivity of this signal. The state of this signal during reset must be the SMBus address for the CNR board.

B23

GND

Power supply and signal ground return path.

A24

SMB_A2

This signal is bit 2 (MSB) of the 3-bit address of the SMBus EEPROM on the CNR board. Refer to Section 6.1.1.2 for detailed information on the connectivity of this signal. The state of this signal during reset must be the SMBus address for the CNR board.

B24

SMB_A0

This signal is bit 0 (LSB) of the 3-bit address of the SMBus EEPROM on the CNR board. Refer to Section 6.1.1.2 for detailed information on the connectivity of this signal. The state of this signal during reset must be the SMBus address of the CNR board.

A25

SMB_SDA

Bi-directional serial data line between the SMBus master to SMBus slave device(s) on the CNR board. For detailed information on this signal, refer to the current version of the System Management Bus Specification. The reset state of this signal must meet the current version of the System Management Bus Specification.

B25

SMB_SCL

Serial clock line from the SMBus master to SMBus slave device(s) on the CNR board. For detailed information on this signal, refer to the current version of the System Management Bus Specification. The reset state of this signal must meet the current version of the System Management Bus Specification.

A26

AC97_RESET#

Active low AC97 link reset signal. For detailed information, refer to the current version of the AC97 Component Specification. The reset state of this signal must meet the requirements of the current version of the AC97 Component Specification.

B26

CDC_DN_ENAB#

CDC_DN_ENAB# indicates whether the motherboard or the CNR is in control, or mastering, the AC97 interface attached to the CNR Connector. When at a logic low level, the CDC_DN_ENAB# signal indicates that the primary codec on the motherboard is active and controlling the AC97 Interface. In addition, the CNR will, when CDC_DN_ENAB# is low, demote its codecs to the next available address and to the next available SDATA_IN signal. See Section 3.3.1 for more details on the implementation of the CDC_DN_ENAB# signal. When at a logic high level, the CDC_DN_ENAB# signal indicates that a primary codec on the CNR is taking control of the AC97 Interface. In addition, the motherboard will, when CDC_DN_ENAB# is high, disable all of its codecs. See Section 3.3.1 for more details of how to implement the CDC_DN_ENAB# signal.

A27

RESERVED

-

RESERVED

B27

GND

Power supply and signal ground return path.

A28

AC97_SDATA_IN1

AC97 serial data from an AC97-compliant codec (primary or secondary) to an AC97-compliant Controller. For detailed information, refer to the current version of the AC97 Component Specification. The reset state of this signal must meet the requirements of the current version of the AC97 Component Specification.

B28

AC97_SYNC

Synchronization pulse from an AC97-compliant controller to all of the AC97- compliant codecs on the AC link. This signal is nominally a 1.3 µS wide pulse, which is used to synchronize the AC link. For detailed information, refer to the current version of the AC97 Component Specification. The reset state of this signal must meet the requirements of the current version of the AC97 Component Specification.

A29

AC97_SDATA_IN0

AC97 serial data from a primary AC97-compliant codec to an AC97-compliant Controller. For detailed information, refer to the current version of the AC97 Component Specification. The reset state of this signal must meet the requirements of the current version of the AC97 Component Specification.

B29

AC97_SDATA_OUT

AC97 serial data from an AC97-compliant controller to all of the AC97- compliant codecs on the link. For detailed information, refer to the current version of the AC97 Component Specification. The reset state of this signal must meet the requirements of the current version of the AC97 Component Specification.

A30

GND

Power supply and signal ground return path.

B30

AC97_BITCLK

Serial data clock from primary codec to AC97 Controller and any non-primary codecs. The nominal frequency of this signal is 12.288 MHz. For detailed information, refer to the current version of the AC97 Component Specification. AC97_BITCLK is an output from a primary codec and an input to non-primary codecs. The reset state of this signal must meet the requirements of the current version of the AC97 Component Specification.